Electronic component mounting apparatus

ABSTRACT

A work mounting apparatus or component mounting apparatus according to the present invention comprises a lower drum of a rotating drum, a head unit arranged on the outer periphery of the lower drum, a circular work head or component head attached to the head unit, and a suction nozzle protruding from the outer peripheral surface of the work head toward a workbench. While the lower drum is rotating, the suction nozzle of the work head repeats cycloid motion along the workbench with its posture kept fixed with respect to the workbench. While repeating the cycloid motion, the nozzle receives a work or component, such as an electronic component from a work feeder of the workbench by suction, and mounts the work on a printed board on the workbench. The work head is rotated for a predetermined rotational angle during the process in which the suction nozzle moves from the work feeder toward the printed board after the work is received, or in the process in which the nozzle moves from the printed board toward the work feeder after the work is mounted. Thus, the region for the cycloid motion of the suction nozzle is upwardly separated from the workbench.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a work mounting apparatus or complement mounting apparatus for mounting an IC chip or some other electronic component, as a work, on a printed board.

2. Description of the Related Art

As used herein, "work" refers to a component or element which is to be retrieved from a supply location and to be mounted upon a device or an element of a device, such as a printed board, by a component mounting apparatus or work mounting apparatus.

A work mounting apparatus of this type is disclosed in Published Unexamined Japanese Patent Application No. 62-114290, for example. This conventional apparatus comprises a rotating table and a plurality of suction heads arranged at predetermined intervals on the outer peripheral edge of the table. Each suction head is capable of up-and-down motion.

A workbench is disposed under the rotating table, and a component or work supply section and a component or work mounting section are arranged on the workbench at a distance from each other in the circumferential direction of the table. A plurality of work feeders or component feeders are radially arranged in the supply section, while a printed board is disposed in the mounting section.

When one of the suction heads is positioned in one of the work feeders of the supply section as the table rotates, the rotation of the table is stopped. In this state, the suction head is lowered, receives a work from the work feeder by suction, and is then raised to its original position. When the rotation of the table is restarted, thereafter, the suction head is transferred from the supply section to the mounting section. When the suction head is positioned in the mounting section, the rotation of the table is stopped again. In this state, the suction head is lowered again, whereupon the work is released from the suction, so that it is mounted on the printed board in the mounting section.

According to the work mounting apparatus described above, the rotation of the table must be stopped every time the suction head is move up or down, that is, every time the work is received or mounted in the supply or mounting section. In other words, the rotation of the table and the operation of the suction head are performed intermittently, so that the tact time cannot be shortened, and therefore, the work mounting efficiency is low.

In these circumstances, there is a demand for continuous-type work mounting apparatuses in which works can be received and mounted without stopping the rotation of the table.

In one such continuous-type mounting apparatus, for example, a continuously rotatable drum, which is used in place of the rotating table, is surrounded by a plurality of work heads which repeat up-and-down motion as they turn. More specifically, the work heads turn around a turning axis which extends in the radial direction of the rotating drum, and their respective postures are kept fixed during the turning motion.

Thus, if a suction nozzle is provided protruding downward from each work head, it can repeat up-and-down motion while moving in the circumferential direction of the rotating drum, as the drum rotates and as the work head turns.

If the turning speed and turning direction of the work head are properly set with respect to the peripheral speed of the rotating drum, moreover, the relative speed of the suction nozzle with respect to the supply and mounting sections, that is, the ground speed, can be reduced substantially to zero when the suction nozzle lowers so that the supply and mounting sections come closest to each other. Even while the rotating drum is being continuously rotated, therefore, the suction nozzle of the work head can securely receive a work from one of the work feeders of the supply section by suction, and then mount the received work head on a printed board in the mounting section.

In order to improve the work mounting efficiency of the continuous-type work mounting apparatus described above, the time required for the movement of the work head from the supply section to the mounting section must be shortened. This can be attained by only increasing the peripheral speed of the rotating drum. If the peripheral speed of the drum is increased, however, the ground speed of the suction nozzle, with respect to the supply and mounting sections, cannot be reduced to zero in the aforesaid manner unless the turning speed of the work head is increased correspondingly.

If the turning speed of the work head is increased, moreover, the cycle of the up-and-down motion of the suction nozzle is inevitably shortened. This indicates that the suction nozzle is frequently moved toward and away from the workbench during the process in which the nozzle moves from the work feeder toward the printed board. In the supply section on the workbench, therefore, the suction nozzle or the work thereon may possibly interfere with the other work feeders or devices on the workbench. This imposes restrictions on the arrangement of the work feeders and various other devices on the workbench.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a work mounting apparatus or component mounting apparatus in which works or components can be mounted in a manner such that suction nozzles can be securely prevented from interfering with work feeders on a workbench and various other devices.

The above object is achieved by a work (or component) mounting apparatus according to the present invention, which comprises: a work supply section disposed in a predetermined transportation path and having a plurality of supply positions arranged along the transportation path, the supply positions being successively supplied with works; a work mounting section disposed at a distance from the supply section, in the transportation path, and having a work mounting surface movable across the transportation path; a carrier repeatedly movable along the transportation path between the mounting section and the supply section; a work head or component provided on the carrier, the work head having a turning axis extending across the transportation path and including a suction nozzle projecting from the work head toward the transportation path; turning means for turning the work head around the turning axis while keeping the work head in a fixed posture with respect to the transportation path, during the movement of the carrier, and subjecting the distal end of the suction nozzle to cycloid motion along the transportation path; supply means for supplying suction pressure to the suction nozzle; control means for controlling the cycle of the cycloid motion of the suction nozzle and the supply of the suction pressure to the suction nozzle, the control means causing one of the works to be attracted to the distal end of the suction nozzle in one target supply position, and then releasing the work from the hold by the suction nozzle at the mounting surface, so that the work is mounted on the mounting surface; and separating means for separating the trace of the cycloid motion, generated by the distal end of the suction nozzle, from the transportation path when the suction nozzle performs neither work attracting operation nor work mounting operation.

According to the work mounting apparatus described above, a predetermined distance can be secured between the distal end of the suction nozzle and the transportation path despite the repeated cycloid motion of the nozzle when the nozzle performs neither the work attracting operation nor the work mounting operation, that is, when the nozzle is situated off the one target supply position and the mounting surface. Thus, if the suction nozzle moves toward the mounting surface while repeating the cycloid motion after the work is attracted thereto, there is no possibility of the work on the nozzle interfering with the device or members on the transportation path side during the process of movement.

The above advantage can be also obtained in like manner during the process in which the suction nozzle moves from the mounting surface toward the target supply position after the work mounting process.

Preferably, the work head has an axis of rotation parallel to the turning axis, and the separating means includes changing means for rotating the work head for a predetermined rotational angle around the axis of rotation thereof, thereby changing the posture of the suction nozzle with respect to the transportation path.

In this case, the supply means for supplying the suction pressure to the suction nozzle includes a suction passage in the work head, the suction passage having one end connected to the suction nozzle and the other end opening in the outer end face of the work head; a control disk in sliding contact with the outer end face of the work head, the control disk airtightly closing the other end opening of the suction passage and being prevented from rotating around the axis of rotation of the work head; a control passage in the control disk, the control passage having one end opening in that surface of the control disk which is in sliding contact with the work head and the other end opening in the outer surface of the control disk, the other end opening being connected to a suction source by means of a suction line; and an arcuate groove formed in one of the respective sliding-contact surfaces of the work head and the control disk, the arcuate groove maintaining the connection between the other end opening of the suction passage and the one end opening of the control passage even though the work head is caused to rotate for said rotational angle around the axis of rotation thereof.

Even if the work head is provided with a plurality of suction nozzles, according to the suction pressure supply means described above, each nozzle and the suction source can be connected with ease.

The above and other objects, features, and advantages of the invention will be more apparent from the ensuing detailed description taken in connection with the accompanying drawings. It is to be expressly understood, however, that the drawings are for purpose of illustration only and are not intended as a definition of the limits of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic side view, partially in section, showing a chip mounter according to one embodiment of the present invention;

FIG. 2 is a schematic plan view showing the chip mounter of FIG. 1 with its upper drum omitted;

FIG. 3 is a sectional view showing a supporting structure for a rotating drum of the chip mounter;

FIG. 4 is an enlarged view showing a coupler for connecting lower and upper drums;

FIG. 5 is a sectional view showing a modification of the coupler;

FIG. 6 is a sectional view showing a drive system in a lower drum, ranging from a drum shaft to a head unit;

FIG. 7 is a sectional view showing the head unit in detail;

FIG. 8 is a front view showing a link arm of the head unit;

FIG. 9 is an end view showing a control disk of the head unit;

FIG. 10 is a front view showing a work head of the head unit;

FIG. 11 is a schematic view illustrating the up-and-down motion of a suction nozzle of the work head;

FIG. 12 is a front view of a brake unit;

FIG. 13 is a sectional view showing a modification of the brake unit;

FIG. 14 is a front view showing the work head immediately before a work is attracted to a suction nozzle;

FIG. 15 is a front view showing the work head at the point of time when the work is attracted to the suction nozzle;

FIG. 16 is a front view showing the work head after the work is attracted to the suction nozzle;

FIG. 17 is a front view showing the work head with the suction nozzle right over an identification camera;

FIG. 18 is a view showing the posture of the work attached to the suction nozzle;

FIG. 19 is a sectional view showing a modification of the head unit;

FIG. 20 is a view showing connectors for electrically connecting a controller on the upper-drum side and various devices on the lower-drum side;

FIG. 21 is a perspective view for illustrating the way of mounting the connectors;

FIG. 22 is a front view showing part of another chip mounter;

FIG. 23 is a sectional view showing part of the chip mounter of FIG. 22;

FIG. 24 is a front view showing part of still another chip mounter; and

FIG. 25 is a sectional view showing part of the chip mounter of FIG. 24.

DETAILED DESCRIPTION

Referring now to FIGS. 1 and 2, there is shown an outline of a chip mounter. The chip mounter generally comprises a ring-shaped workbench 2 and a rotating drum 4 arranged over the workbench 2. The drum 4 is rotatable within a horizontal plane.

A large number of work feeders or component feeders 6 are mounted in a radial shape on the workbench 2. These work feeders 6 can continuously feed various electronic components or works, such as IC chips, resistors, capacitors, etc., into a predetermined position on the workbench 2.

The work feeders 6 are arranged at regular intervals in the circumferential direction of the workbench 2, each feeder 6 constituting a work supply section. FIG. 2 shows only two of the work feeders 6 or supply sections.

As seen from FIG. 2, the workbench 2 is partially cut, and a mounting section is disposed in the cut region. The mounting section includes an XY-table 8, which has a table face 10. The table face 10 can be moved in the X-direction of FIG. 2 by means of an electric motor 12, and in the Y-direction by means of another electric motor 14. The Y-direction is perpendicular to the X-direction.

The table face 10 is defined by an endless belt, which is run in the A-direction of FIG. 2 by means of an electric motor 16. The A-direction is coincident with the Y-direction.

Conveyors 18 and 20 are arranged close to each other on the opposite sides of the table face 10, individually, with respect to the A-direction. Each of these conveyors 18 and 20, like the table face 10, includes an endless belt.

The table face 10 and the conveyors extend in alignment with one another, and the conveyors 18 and 20 can be run in the A-direction by means of electric motors 22 and 24, respectively.

A printed board B is fed onto the one conveyor 18. In FIG. 2, the printed board B is kept on standby on the conveyor 18. If the table face 10 is moved long in the Y-direction toward the conveyor 18, it is connected to the conveyor 18. When the conveyor 18 and the belt of the table face 10, in this state, are run together in the A-direction, the printed board B on the conveyor 18 is allowed to be transferred to the table face 10.

If the table face 10 is moved long in the Y-direction toward the conveyor 20, on the other hand, it is connected to the conveyor 20. When the table face 10 and the belt of the conveyor 20 are run together in the A-direction, in this case, the printed board B on the table face 10 is discharged onto the conveyor 20.

Thus, the one conveyor 18 has a function to carry in the printed board B onto the table face 10, while the other conveyor 20 has a function to carry out the printed board B from the table face 10.

A work supply position on the workbench 2, which is defined by each work feeder 6, and the printed board B on the table face 10 are on the same level. In FIG. 2, symbol Z designates a region in which the work feeders 6 can be set.

As shown in FIG. 1, the rotating drum 4 comprises an upper drum 26 and a lower drum 28 which are divided in the vertical direction. The lower drum 28 is rotatably supported on a drum base 30 by means of a drum shaft 32. The drum base 30 is located in the center of the workbench 2. The upper drum 26 is rotatably suspended from a frame 34, which surrounds the whole chip mounter. The upper and lower drums 26 and 28 are connected to each other by means of a plurality of couplers 36.

FIG. 3 shows a supporting structure for the drum shaft 32 on the drum base 30, a supporting structure for the upper drum 26 on the frame 34, and a connecting structure for the lower drum 28 on the drum shaft 32.

The drum shaft 32 extends vertically through the center of the drum base 30, and a drive motor 40 is connected to the lower end of the shaft 32 by means of a speed reducer 38. The motor 40 and the reducer 38 are attached to the lower end of a fixed sleeve 44 by means of a holder 42 and a plurality of connecting bolts 46. The sleeve 44, which surrounds the drum shaft 32, has its lower end fixed to the drum base 30.

The upper drum 26, which is a hollow structure, is rotatably suspended from the frame 34 by means of a supporting shaft 48. More specifically, the upper end of the shaft 48 is rotatably supported on the frame 34, and a bottom plate 52 of the upper drum 26 is connected to the lower end of the shaft 48 by means of a flange 50. Further, a bearing unit 55 is mounted on the frame 34 so as to surround the supporting shaft 48.

The supporting shaft 48 of the upper drum 26 and the drum shaft 32 are situated on the same axis. A gap of a predetermined size is defined between the bottom plate 52 of the upper drum 26 and the upper end of the drum shaft 32.

The lower drum 28 has a boss 54 in the center, which is connected to the drum shaft 32 by means of a plurality of connecting bolts 56.

As seen from FIG. 2, the four couplers 36, which connect the lower and upper drums 28 and 26, are arranged at regular intervals on the circumference of the same circle. Since these couplers 36 have the same construction, one of them will be described in detail with reference to the drawing of FIG. 4.

The coupler 36 comprises a lower connecting bracket 57 protruding from the upper surface of the lower drum 28 and a pair of upper connecting brackets 58 suspended from the upper drum 26. The upper brackets 58 are situated individually on the opposite sides of the lower bracket 57 with respect to the circumferential direction of the lower drum 28. The lower bracket 57 and the paired upper brackets 58 are connected to one another by means of two leaf springs 60 which are joined together. The springs 60 are fixed to the lower connecting bracket 57 at the center by means of a connecting bolt-nut assembly 62. The respective opposite ends of the leaf springs 60 are fixed to their corresponding upper connecting brackets 58 by means of connecting bolt-nut assemblies 64, individually.

Further, the coupler 36 comprises a sensor 66 for detecting the occurrence of breakage of the leaf springs 60. As shown in FIG. 4, the sensor 66 of this type is mounted on the lower surface of the upper drum 26, and has a contact 67 which touches the springs 60. Thus, when voltage is applied between the paired upper connecting brackets 58, the sensor 66 can detect electric current flowing through the leaf spring 60, and output a detection signal indicative of this current. The detection signal from the sensor 66 is supplied to a controller 69 (see FIG. 3) which is disposed in the upper drum 26. In response to the detection signal from the sensor 66, the controller 69 can detect the occurrence of breakage of the leaf springs 60.

The coupler 36 is not limited to the one shown in FIG. 4, and a coupler 36 shown in FIG. 5 may be used in place of the coupler of FIG. 4. The coupler 36 of FIG. 5 differs from the coupler of FIG. 4 only in that its leaf springs 60 are previously curved in the shape of a circular arc along the circumferential direction of the lower drum 28.

When the drive motor 40 is driven, the lower drum 28 is rotated in the direction of arrow C of FIG. 2 through the medium of the drum shaft 32. The rotatory force of the lower drum 28 is transmitted to the upper drum 26 through the couplers 36, so that the upper drum 26 is rotated integrally with the lower drum 28.

The lower drum 28 is provided with a large number of head units 68 which are used to take out works in the respective supply positions of the work feeders 6, and then mount them on the printed board B. These head units 68 are arranged at regular intervals in the circumferential direction of the lower drum 28.

The head units 68, which are shown only schematically in FIGS. 1 and 2, have the same construction and are situated in the same radial position with respect to the lower drum 28. The following is a description, therefore, of only one of the units 68.

FIGS. 6 and 7 individually show in detail a specific arrangement of the head unit 68 and a drive system for the unit 68. Referring first to FIG. 7, the construction of the head unit 68 will be described.

The head unit 68 comprises a work head or component head 70, which is positioned protruding from the outer peripheral edge of the lower drum 28. The head 70 includes a cylindrical head housing 72, whose axis extends in the radial direction of the lower drum 28. Thus, the head housing 72 has two opposite end faces which cross the radial direction of the lower drum 28 at right angles. The outer one of these end faces is open. This open end face is closed by means of a cover 74.

Four pipe-shaped nozzle holders 76 are provided on the peripheral wall of the head housing 72. These holders 76, which are arranged at regular intervals in the circumferential direction of the head housing 72, are attached to the housing 72 so as to penetrate the peripheral wall thereof. Further, the nozzle holders 76 are supported on the head housing 72 for rotation around their respective axes. Thus, the holders 76 protrude radially from the peripheral wall of the head housing 72.

A suction nozzle 78 is attached to each nozzle holder 76 so as to penetrate it. More specifically, an axial flattened portion 80 is formed in that part of the suction nozzle 78 which is situated in the nozzle holder 76, and a stopper bolt 82 is screwed into the holder 76 through the flattened portion 80 of the nozzle 78. Thus, the suction nozzle 78 can be rotated integrally with the nozzle holder 76 around its axis by means of the bolt 82. With respect to its axial direction, however, the nozzle 78 can move relatively to the holder 76 only for a distance corresponding to the length of the flattened portion 80.

The outer end of each suction nozzle 78 projects outward from the nozzle holder 76, and is provided with a suction port (not shown). The respective suction ports of the nozzles 78 are different in size from one another, depending on the sizes of the works to be attracted thereto.

A disk-shaped guide holder 84 is disposed in the central portion of the head housing 72. Guide holes 86 are formed radially in the peripheral surface of the guide holder 84, corresponding individually to the suction nozzles 78. Thus, the respective inner ends of the nozzles 78 projecting from the nozzle holders 76 are slidably fitted in their corresponding guide holes 86 of the guide holder 84. Further, the guide holder contains a ball 88, which is situated in the region where the guide holes 86 get together, and closes the respective inner ends of the holes 86. In each guide hole 86, a coil spring 90 is interposed between the inner end of the suction nozzle 78 and the ball 88. The spring 90 continually urges its corresponding nozzle 78 to the outside with respect to the radial direction of the work head 70, that is, in the direction to project from the head 70.

A first spindle 92 extends from the head housing 72 toward the lower drum 28. The axis of the spindle 92 is coaxial with the housing 72. One end of the spindle 92, which is situated in the head housing 72, supports the guide holder 84. A side gear 94, formed of a bevel gear, is mounted on one end portion of the first spindle 92 by means of a key. The diameter of the gear 94 is greater than that of the guide holder 84. Each nozzle holder 76 has a pinion 96, in the form of a bevel gear, on its inner end. The pinions 96 are in mesh with the side gear 94.

Meanwhile, a toothed pulley or nozzle driving pulley 98 is mounted on the other end of the first spindle 92. When an external rotatory force is transmitted to the pulley 98, it is transmitted from the pulley 98 to the side gear 94 through the spindle 92. Then, the rotatory force is transmitted from the gear 94 to the individual nozzle holders 76 through the pinions 96. Thus, the holders 76 and their corresponding suction nozzles 78 are rotated around their respective axes.

A hollow second spindle 100 is coaxially fitted on the first spindle 92. Both ends of the second spindle 100 are rotatably supported on the first spindle 92 by means of a pair of bearings, individually. The second spindle 100 extends from the head housing 72 to the nozzle driving pulley 98. A flange 102 is formed on one end of the second spindle 100 which is situated on the side of the housing 72. The flange 102 is connected to the housing 72 by means of a plurality of connecting bolts 104. Thus, the head housing 72 can rotate together with the second spindle 100. A head driving pulley 106 formed of a toothed pulley is mounted on the other end of the second spindle 100. The pulley 106 is situated adjacent to the nozzle driving pulley 98. When an external rotatory force is transmitted to the pulley 106, the pulley 106 causes the head housing 72 to rotate through the medium of the second spindle 100. Thus, the second spindle 100 serves as the axis of rotation of the housing 72 or the work head 70.

Further, a hollow third spindle 108 is coaxially fitted on the second spindle 100. Both ends of the third spindle 108 are rotatably supported on the second spindle 100 by means of a pair of bearings, individually. The third spindle 108 extends from the flange 102 of the second spindle 100 to the head driving pulley 106.

A link arm 110, which extends from the third spindle 108, is connected integrally to the spindle 108. More specifically, a flange 112 is formed on that end portion of the third spindle 108 which is situated on the side of the head driving pulley 106. The flange 112 is connected to the link arm 110 by means of a plurality of connecting bolts 114.

The link arm 110 is formed of a plate member, such as the one shown in FIG. 8. A fitting hole 116 for the third spindle 108 is formed at one end portion of the plate member, and tapped holes 118 for the connecting bolts 114 are formed around the hole 116.

Further, a center hole 120 is formed in the link arm 110, and a semicircular recess 122 is formed at the other end of the arm 110. The recess 122 and the center hole 120 are connected by means of a slit 124, and a notch groove in line with the slit 124 is formed on the inner peripheral surface of the hole 120.

As shown in FIG. 7, a balance weight 126 is fitted in the recess 122 of the link arm 110. The weight 126 is fixed to the arm 110 by means of a plurality of connecting bolts 128. As shown in FIG. 8, therefore, tapped holes 130 for the bolts 128 are formed in the link arm 110 so as to surround the recess 122.

The balance weight 126 is substantially as heavy as the head unit 68 which is connected to the one end of the link arm 110.

A control disk 132 is rotatably mounted on the third spindle 108. The disk 132 has a stepped configuration, and its large-diameter portion is in engagement with the head housing 72. A hole is formed in the center of the end face of the large-diameter portion of the disk 132. This hole has a diameter greater than that of the flange 102 of the second spindle 100. Thus, the end face or ring-shaped end face 136 of the large-diameter portion of the control disk 132 can engage the head housing 72 without being hindered by the flange 102 of the second spindle 100.

A coil spring 134 is disposed between a small-diameter portion of the control disk 132 and a step on the third spindle 108 so as to surround the spindle 108. The spring 134 presses the ring-shaped end face 136 of the disk 132 against the head housing 72. Thus, the end face 136 and the end face of the housing 72 are airtightly in sliding contact with each other.

As shown in FIG. 9, an arcuate groove 138 is formed in the sliding-contact surface 136 of the control disk 132. As shown in FIG. 7, on the other hand, suction holes 140 open in the end face of the head housing 72. The respective openings of the holes 140 are arranged at regular intervals in the circumferential direction of the housing 72. Each suction hole, which is not shown in detail, continually communicates with its corresponding suction nozzle 78 by means of the nozzle holder 76.

In the state shown in FIG. 9, one of the suction holes 140 of the head housing 72 is connected to the arcuate groove 138 of the control disk 132, and is then situated at one end of the groove 138. As seen from FIG. 7, the distal end of the suction nozzle 78 associated with the connected suction hole 140 faces downward.

Even when the head housing 72 or the work head 70 is rotated for a predetermined rotational angle α (e.g., 45°) in the direction of arrow D of FIG. 9, the connection between the arcuate groove 138 and the suction hole 140 can be maintained. Therefore, the groove 138 has a length equivalent to the rotational angle α of the work head 70.

A control hole 142 is formed in the control disk 132. One end of the hole 142 is connected to the arcuate groove 138, and the other end thereof opens in that end face of the disk 132 on the opposite side to the sliding-contact surface 136. The opening of the control hole 142 is connected to a flexible tube 146 by means of a connecting plug 144. The tube 146 is connected to a suction circuit, which will be mentioned later. Thus, when a suction pressure from this suction circuit is supplied to the suction nozzle 78 through the tube 146, control hole 142, arcuate groove 138, and suction hole 140, the nozzle 78 is enabled to attract a work to its suction port.

A disk pulley 148 formed of a toothed pulley is mounted on the small-diameter portion of the control disk 132.

The head unit 68 is removably connected to the drive system on the side of the lower drum 28.

The drive system of the lower drum 28 comprises a shaft assembly 150, which extends in the radial direction of the drum 28. Part of the assembly 150 includes a quadruple-shaft portion, which is positioned projecting from the outer peripheral portion of the lower drum 28. Thus, the quadruple-shaft portion is situated in the vicinity of the head unit 68.

The quadruple-shaft portion includes a fixed shaft 152 on the center side and first, second, and third sleeve shafts 154, 156 and 158 rotatably fitted on the shaft 152 in succession.

One end portion of the first sleeve shaft 154 projects outward from the second and third sleeve shafts 156 and 158 with respect to the radial direction of the lower drum 28. The link arm 110 of the head unit 68 is removably connected to this projecting end portion of the first sleeve shaft 154. More specifically, the one end portion of the first sleeve shaft 154 is fitted in the center hole 120 of the arm 110. A tapped hole 162 (see FIG. 8), which extends across the slit 124, is formed in a side face of the arm 110. A connecting screw 160 is screwed in the hole 162. As the screw 160 is thus screwed in, the slit 124 of the arm 110 is narrowed so that the center hole 120 is reduced in diameter. As a result, the connection between the link arm 110 and the first sleeve shaft 154 is established.

As seen from FIG. 6, the other end side of the first sleeve shaft 154 extends inward from the quadruple-shaft portion with respect to the radial direction of the lower drum 28, and penetrates an inside drum wall 28a which protrudes from the lower surface of the drum 28. Thus, the other end portion of the shaft 154 is rotatably supported by the wall 28a.

Besides the inside drum wall 28a, an outside drum wall 28b is formed on the lower surface of the lower drum 28 so as to surround the wall 28.

Further, both ends of the fixed shaft 152 extend penetrating the first sleeve shaft 154. More specifically, one end portion of the shaft 152 projects from the link arm 110, as shown in FIG. 7. An fixed pulley 164 formed of a toothed pulley is mounted on the one end of the fixed shaft 152 by means of a mounting bolt (not shown). A toothed belt 166 is passed around and between the pulley 164 and the disk pulley 148.

As shown in FIG. 6, on the other hand, the other end of the fixed shaft 152 projects from the first sleeve shaft 154, and is supported by the lower drum 28. A thrust bearing 168 for receiving a thrust force from the first sleeve shaft 154 is mounted on the other end portion of the fixed shaft 152.

As shown in FIG. 7, the second sleeve shaft 156 has one end situated in the vicinity of the link arm 110, and extends inward for a predetermined length, with respect to the radial direction of the lower drum 28. An output pulley 170 formed of a toothed pulley is provided on the one end of the second sleeve shaft 156. A toothed belt 172 is passed around and between the output pulley 170 and the head driving pulley 106. The other end portion of the second sleeve shaft 156 penetrates a bearing unit 174, and is rotatably supported by the unit 174. The bearing unit 174 is fixed to the outside drum wall 28b of the lower drum 28.

Further, the third sleeve shaft 158 extends between the output pulley 170 of the second sleeve shaft 156 and the bearing unit 174. An output pulley 176 formed of a toothed pulley is mounted on one end of the third sleeve shaft 158. A toothed belt 178 is passed around and between the output pulley 176 and the nozzle driving pulley 98.

A predetermined tension is applied to each of the three toothed belts 166, 172 and 178 by means of a plurality of tension rollers 180 shown in FIGS. 6 and 7. The tension rollers 180 are rotatably mounted on roller shafts which extend from the link arm 110. As shown in FIG. 8, therefore, mounting holes 182 for the roller shafts are formed in the arm 110.

The pulley ratio between each pulley of the shaft assembly 150 and its corresponding pulley of the head unit 68 is set at 1:1. Thus, even if the first sleeve shaft 154 is rotated by means of an external driving force when the respective output pulleys 170 and 176 on the second and third sleeve shafts 156 and 158, as well as the pulley 164 on the fixed shaft 152, are stopped from rotating, the head unit 68 rotates around the first sleeve shaft 154. At this time, the work head 70 is caused to turn around the first sleeve shaft 154 by the link arm 110, that is, the shaft 154 serves as a pivot of the head 70.

When the work head 70 turns in this manner, the toothed belts 166, 172 and 178, which are passed around and between the pulleys 148, 106, and 98 and their corresponding pulleys on the side of the shaft assembly 150, are restrained from rotating. In this case, therefore, the work head 70 keeps its posture fixed as it turns around the first sleeve shaft 154. Thus, the pulleys of the shaft assembly 150, pulleys of the head unit 68, and toothed belts constitute a planetary mechanism, which causes the work head 70 to turn while maintaining the posture of each suction nozzle 78 of the head 70. Accordingly, when one of the nozzles 78 of the head 70 faces downward, its downward posture can be maintained despite the turn of the work head 70.

Since the control disk 132 turns together with the work head 70 around the first sleeve shaft 154, these members can never rotate relatively to each other. Despite the turn of the disk 132 and the head 70, therefore, the arcuate groove 138 of the disk 132 and that suction hole 140 of the head housing 72 which is connected to the groove 138 can be kept connected to each other.

Referring now to FIG. 6, a power transmission path for the first sleeve shaft 154 will be described.

A bevel gear 184 is mounted on the other end of the first sleeve shaft 154. The gear 184 is in mesh with an output bevel gear 188 of a differential gear system 186. The output gear 188 is mounted on an output shaft of the system 186. The differential gear system, which is generally called a harmonic drive system, is fixedly mounted on the lower drum 28.

The differential gear system 186 includes an input pinion 190 and a toothed input pulley 192 on its input side. The input pinion 190 is in mesh with a ring gear 194, which is fixed, by means of a plurality of fixing bolts 196, to the fixed sleeve 44 which surrounds the drum shaft 32, as mentioned before.

The input pulley 192 is connected to an output pulley (not shown in detail) of a first control motor 200 by means of a toothed belt 198. The motor 200 is also supported by the lower drum 28.

As the lower drum 28 rotates, therefore, the differential gear system 186 can receive an input from the input pinion 190, which is rotated by means of the ring gear 194, and also may receive an input from the input pulley 192, which is rotated by means of the first control motor 200.

When the lower drum 28 is first rotated by means of the drive motor 40 with the first control motor 200 off, the differential gear system 186 turns around the drum shaft 32. Accordingly, the input pinion 190 of the system 186 is rotated by means of the fixed ring gear 194. Since the rotatory force of the pinion 190 is transmitted to the first sleeve shaft 154 through the output bevel gear 188 of the differential gear system 186 and the bevel gear 184, the shaft 154 is also rotated. As a result, the work head 70 turns around the first sleeve shaft 154 in association with the rotation of the lower drum 28, while maintaining its posture, as mentioned before.

The turning direction of the work head 70 is indicated by arrow E in FIG. 10, and the rotating direction of the lower drum 28 by arrow C. When the pivot of the head 70 or the first sleeve shaft 154 moves from right to left of FIG. 10 as the lower drum 28 rotates, the turning direction E of the head 70 is adjusted to the counterclockwise direction. When the work head 70 descends toward the workbench 2, therefore, the head 70 and the workbench 2 move in opposite directions.

If the workbench 2 is situated above the work head 70 as in FIG. 10, the turning direction of the head 70 is opposite to the direction E.

When the first control motor 200 is not driven, the power transmission system including the differential gear system 186 makes the peripheral speed of the lower drum 28 or the speed of revolution of the work head 70 around the drum shaft 32 equal to the turning speed of the head 70 or that of the distal end of each suction nozzle, to be exact.

When the rotation of the lower drum 28 and the turning motion of the work head 70 are concurrent, the head 70 repeats a cycloid motion, as shown in FIG. 11. More specifically, the downward suction nozzle 78 of the work head 70 moves so that its distal end generates a cycloid, and repeats up-and-down motion to approach and leave the workbench 2. FIG. 11 also shows change of the speed of movement of the suction nozzle 78 relative to the workbench 2, that is, ground speed V of the nozzle 78. The ground speed V is nearly zero when the suction nozzle 78 is situated in the lower limit position of its up-and-down motion, and is the highest when the nozzle 78 is in its upper motion limit position. The change of the ground speed V indicates the off-state of the first control motor 200.

If the first control motor 200 is driven so that the input pulley 192 of the differential gear system 186 is rotated while the lower drum 28 is rotating, however, the rotating speed of the output shaft or output bevel gear 188 of the system 186, that is, the turning speed of the work head 70, changes. By controlling the drive of the input pulley 192 or the first control motor 200, therefore, the turning speed of the head 70, that is, the cycle L of the cycloid motion of the downward suction nozzle 78, can be varied as required.

The following is a more specific description of the control of the cycloid motion of the work head 70.

Let it be supposed that the up-and-down motion of the head 70 is repeated N number of times if the work head 70 moves along a revolution path, which extends from the work feeder 6 in a position P1 in FIG. 2 to the table face 10 of the XY-table 8, that is, the printed board B, when the drive of the first control motor 200 is stopped. If the turning speed of the work head 70, that is, the cycle L of the cycloid motion thereof, in this state, is varied by the first control motor 200 through the medium of the differential gear system 186, the frequency of the up-and-down motion of the head 70 changes to N±x as the head 70 moves along the revolution path.

This indicates that the downward suction nozzle 78 of the work head 70 can descend to any desired position with respect to the circumferential direction of the workbench 2. Accordingly, the nozzle 78 of the head 70 can access not only any desired work feeder 6 on the workbench 2, but also any position on the revolution path which passes over the printed board B on the XY-table 12.

When the suction nozzle 78 descends toward the work feeder 6 or the printed board B, however, the control of the turning speed of the work head 70 is suspended. When the nozzle 78 reaches its lower motion limit position over the work feeder 6 or the printed board B, therefore, its ground speed V never fails to become zero.

As shown in FIG. 6, a brake unit 202 is arranged on the first sleeve shaft 154. As shown in detail in FIG. 12, the unit 202 comprises a brake drum 204 which is fixed to the first sleeve shaft 154. A brake band 206 is passed around the drum 204. One end of the band 206 is connected, by means of a tension coil spring 210 and an adjust screw 211, to a bracket 208 which is fixed to the lower drum 28. The other end of the band 206 is connected directly to the bracket 208. The spring 210 and the screw 211 have a function to adjust a frictional force between the brake drum 204 and the brake band 206, that is, a braking force against the rotation of the first sleeve shaft 154.

In this arrangement, the brake unit 202 continually applies a fixed torque to the first sleeve shaft 154 in the rotating direction thereof. This torque serves to prevent backlash of engagement between the bevel gear 184 on the side of the shaft 154 and the output bevel gear 188 on the side of the differential gear system 186. Thus, the first sleeve shaft 154 can be prevented from undergoing an undesired rotational angle displacement which is attributable to backlash of engagement. Also, the rotating speed of the shaft 154 or the turning speed of the work head 70 can be controlled with high accuracy.

The brake unit 202 is not limited to the one shown in FIG. 12, and may be replaced with one shown in FIG. 13. The brake unit of FIG. 13 uses, in place of the brake band 206 of FIG. 12, a press member 214 which includes a brake pad 212. The brake pad 212 of the press member 214 is pressed against the brake drum 204 by means of a pair of compression coil springs 216 which are arranged between the member 214 and the bracket 208. The urging force of each spring 216 can be adjusted by means of adjust screws 218.

As seen again from FIG. 7, toothed input pulleys 220 and 222 are mounted on the respective other ends of the second and third sleeve shafts 156 and 158, respectively. The pulleys 220 and 222 are connected to output pulleys 232 and 234, on the sides of second and third control motors 228 and 230, by means of toothed belts 224 and 226, respectively. As shown in FIG. 6, the motors 228 and 230 are mounted on the lower drum 28 by means of brackets 236, individually.

Thus, when the second and third control motors 228 and 230 are driven, the second and third sleeve shafts 156 and 158 are also rotated by means of their corresponding toothed belts. As mentioned before, the second sleeve shaft 156 and the second spindle 100 of the head unit 68 are connected to each other by means of the pulleys 170 and 106 and the belt 172. When the second sleeve shaft 156 is rotated, therefore, the second spindle 100 is also rotated, so that the work head 70 rotates on its own axis.

Further, the third sleeve shaft 158 and the first spindle 92 of the head unit 68 are connected by means of the pulleys 176 and 98 and the belt 178. When the third sleeve shaft 158 is rotated, therefore, the first spindle 92 is rotated, so that each suction nozzle 78, along with its corresponding nozzle holder 76, rotates around its axis, as mentioned before.

The suction circuit shown in FIG. 6 is one used for one of the head units 68. The following is a description of this suction circuit.

The suction circuit comprises a vacuum pump 238. A connecting line 240 extends from the pump 238, and is connected to a radial hole 242 in the fixed sleeve 44 by means of a connector 242.

An annular groove 246 is formed on the outer peripheral surface of the drum shaft 32 in the fixing sleeve 44 so that it communicates with the radial hole 242 at all times. The groove 246 is connected to an internal passage 248 of the drum shaft 32, which axially extends in the shaft 32 to the upper end thereof. The upper end of the passage 248 is closed by means of a plug. The upper end portion of the passage 248 is connected to a connecting line 252 by means of a connector 250. The line 252, which extends toward the head unit 68, is connected to one port 256 of a control valve 254.

In the case of this embodiment, moreover, the suction circuit is provided with a pneumatic pressure source 258, which is connected to a radial hole 264 in the fixed sleeve 44 by means of a connecting line 260 and a connector 262.

An annular groove 266, which communicates with the radial hole 264 at all times, is formed on the outer peripheral surface of the drum shaft 32. The groove 266 is connected to an internal passage 268 of the shaft 32. The passage 268, like the aforesaid internal passage 248, extends to the upper end of the drum shaft 32, and its upper end is closed by means of a plug. The upper end portion of the passage 268 is connected to a connecting line 272 by means of a connector 270. The line 272, which extends toward the head unit 68, is connected to one input port 276 of a selector valve 274.

A line 278, which diverges from the middle of the connecting line 272, is connected to another input port 280 of the selector valve 274. A pressure regulating valve 282 is provided in the middle of the line 278.

An output port 284 of the selector valve 274 is connected to another port 288 of the control valve 254 by means of a connecting line 286.

Further, the control valve 254 is provided with still another port 290, besides the ports 256 and 288. The port 290 is connected to the connecting plug 144 of the head unit 68 by means of the tube 146.

The control valve 254 and the selector valve 274 are formed of a solenoid-operated directional control valve of a three-port two-position type (not shown in detail) each. Thus, when the control valve 254 is in one shift position or suction position the port 290 of the valve 254 is connected to the first port 256. When the control valve 254 is shifted from the suction position to the other shift position or blow position, the port 290 is connected to the second port 288.

When the selector valve 274 is in one shift position or high-pressure position, the output port 284 of the valve 274 is connected to the one input port 276. When the valve 274 is shifted from the high-pressure position to the other shift position or low-pressure position, the output port 284 is connected to the other input port 280.

The pressure regulating valve 282 reduces a blow pressure supplied from the pneumatic pressure source 258 to a predetermined pressure level, and supplies it to the input port 280 of the selector valve 274.

The control valve 254, selector valve 274, and pressure regulating valve 282 are all fixedly arranged on the lower drum 28.

The connecting lines 240 and 260, which extend from the vacuum pump 238 and the pneumatic pressure source 258, respectively, are always connected to their corresponding connecting lines 252 and 272 through the internal passages 248 and 368 of the drum shaft 32, respectively, without regard to the rotation of the shaft 32.

Thus, when the control valve 254 is in the suction position, the tube 146 or the downward suction nozzle 78 of the work head 70 is connected to the connecting line 252 through the valve 254, and can be supplied with the suction pressure from the line 252. When the control valve 254 is shifted to the blow position, the suction nozzle 78 of the work head 70 is connected to the connecting line 272 through the valve 254, connecting line 286, and selector valve 274, and can be supplied with the blow pressure from the line 272. The blow pressure supplied to the nozzle 78 can be varied in two stages by changing the shift position of the selector valve 274.

An identification camera 292 is provided at one end of the workbench 2. As shown in FIG. 2, the camera 2 is located on the upper-course side of the XY-table 8 with respect to the rotating direction C of the lower drum 28. The camera 292, which is situated just below the surface level of the workbench 2, faces upward. Thus, when the work head 70 of the head unit 68 passes over the identification camera 292 as the lower drum 28 rotates, the camera 292 photographs the work attached to the downward suction nozzle 78 of the head 70. In this case, the nozzle 78 of the head 70 must be situated on its lowest level when it reaches the position nearest to the camera 292, that is, the position corresponding to the camera 292.

Thus, while the work head 70 is in turning motion as it revolves around the drum shaft 32, the downward suction nozzle 78 of the head 70 is situated on the lowest level when it reaches the position corresponding to the identification camera 292 and then a predetermined position or work mounting position P2 (see FIG. 2) on the printed board B on the XY-table 8. While the work head 70 moves from the location of the camera 292 to the mounting position P2, it makes an integral number of turns.

When the work head 70 moves from the location of the camera 292 to the mounting position P2, on the other hand, the toothed belt 172, which connects the output pulley 170 and the head driving pulley 106 of the head unit 68, travels for a distance equal to an integral multiple of its overall length. Thus, the state of engagement of the belt 172 with the pulleys 170 and 106 established when the location of the camera 292 is reached by the downward suction nozzle 78 of the work head 70 never fails to be reproduced when the mounting position P2 is reached by the nozzle 78.

As shown in FIG. 2, moreover, a work recovery container is arranged at the other end of the workbench 2 so as to be situated on the lower-course side of the XY-table 8 with respect to the rotating direction C of the lower drum 28. Only an opening 294 of the recovery container is shown in FIG. 2.

The first to third control motors 200, 228 and 230, the control valve 254 and the selector valve 274 of the suction circuit, the identification camera 292, rotary encoders designated by numeral 296 in FIG. 6, etc. are connected electrically to the controller 69 (see FIG. 3), which is housed in the upper drum 26. The controller 69 is also connected electrically to a computer (not shown). In this arrangement, the controller 69 receives an image signal from the camera 292, rotational angle signals from the rotary encoders 296, and a control signal from the computer, and controls the control motors 200, 228 and 230 and the valves 254 and 274 in accordance with these signals.

Referring additionally to FIGS. 14 to 18, the operation of the aforementioned chip mounter will now be described. In these drawings, subscripts a, b, c and d are affixed to reference numeral 78 which designates each suction nozzle of the work head 70. If the subscripts are thus affixed to numeral 78, it becomes evident that the posture of each nozzle 78 with respect to the workbench 2 makes no change even though the work head 70 is in turning motion.

FIG. 14 shows a state in which the work head 70 is situated right over the work feeder 6 in the position P1 of FIG. 2 during the rotation of the lower drum 28. At this time, the work head 70 is turning toward the workbench 2, as indicated by arrow E, and the turning speed of the head 70 is equal to the peripheral speed of the lower drum 28, that is, the speed of revolution of the head itself.

In the state shown in FIG. 14, the controller 69 in the upper drum 26 shifts the control valve 274 of the suction circuit to the suction position, so that the suction pressure from the vacuum pump 238 is supplied to the downward suction nozzle 78a of the work head 70.

When the rotation of the lower drum 28 advances from the state of FIG. 14, thereafter, the suction nozzle 78a of the work head 70 further descends toward the position P1 on the workbench 2, and reaches the position of FIG. 15. In this state, the nozzle 78a of the head 70 is situated on the lowest level in the position P1. At this time, the speed of the nozzle 78a with respect to the workbench 2, that is, the ground speed V, becomes substantially zero, as mentioned before, so that the nozzle 78a can securely attracts thereto, by its suction pressure, the work W fed to the position P1 by the work feeder 6.

When the rotation of the lower drum 28 and the turning motion of the work head 70 further advance, thereafter, the suction nozzle 78a turns in the direction to go away from the workbench 2 without leaving hold of the work W. At this time, the controller 69 executes drive control of the second control motor 228, that is, drives the motor 228. The driving force of the second control motor 228 is transmitted to the work head 70 through the toothed belt 224, input pulley 220, second sleeve shaft 156, output pulley 170, toothed belt 172, head driving pulley 106, and second spindle 100, and the head 70 rotates on its own axis for the aforesaid rotational angle α in the direction of arrow D, as shown in FIG. 16. As a result, the work head 70 assumes the rotational posture shown in FIG. 16.

Even though the work head 70 rotates on its own axis, the control hole 142 of the control disk 132 and one of the suction holes 140 of the work head 70 are kept connected to each other by means of the arcuate groove 138, as shown in FIG. 9. Thus, the supply of the suction pressure to the suction nozzle 78a is continued, and the nozzle 78a keeps on holding the work W.

When the work head 70 rotates on its own axis in the aforesaid manner, the lower end of the suction nozzle 78a is raised by a height H, as shown in FIG. 16. After this, therefore, the nozzle 78a of the head 70 repeats its up-and-down motion within the region above the workbench 2 for the height H, at the least. Thus, when the work head 70 then passes over its adjoining work feeder 6, there is no possibility of the suction nozzle 78a interfering with the other work feeders on the workbench 2 or other mechanical members.

When the rotation of the lower drum 28 further advances so that the work head 70 reaches the position just short of the identification camera 292, thereafter, the controller 69 drives the second control motor 228 to restore the head 70 to its original posture, whereupon the suction nozzle 78a of the head 70 faces downward again. Thus, when the nozzle 78a reaches its lowest position right over the camera 292, as shown in FIG. 17, the work W attached to the nozzle 78a faces the camera 292, whereupon the camera 292 photographs the work W. In this manner, the posture of the work W on the suction nozzle 78a can be clearly identified by means of the identification camera 292.

Image data on the work W, obtained by means of the identification camera 292, is supplied to the controller 69. Based on this image data, the controller 69 determines whether or not the work W is held in a right posture on the suction nozzle 78.

More specifically, the controller 69 determines whether or not the posture of the work W is deviated from vertical and horizontal reference lines shown in FIG. 18. If the posture of the work W is deviated from the reference lines beyond the tolerance limits, as indicated by broken line in FIG. 18, the controller 69 drives the third control motor 230, depending on the degree and direction of the deviation of the work posture. The driving force of the third control motor 230 is transmitted to the first spindle 92 through the toothed belt 266, input pulley 222, third sleeve shaft 158, output pulley 176, toothed belt 178, and nozzle driving pulley 98, and causes the spindle 92 to rotate. Since the rotatory force of the first spindle 92 is transmitted to the suction nozzle 78a through the side gear 94, pinion 96, and nozzle holder 76, the nozzle 78a is also rotated around its axis. Thereupon, the posture of the work W is corrected, as indicated by full line in FIG. 18.

As the lower drum 28 rotates, thereafter, the work head 70 moves toward the printed board B on the XY-table 8 while repeating the turning motion. When the suction nozzle 78a of the head 70 reaches the mounting position P2 on the printed board B, it is situated on the lowest level as in the case for the position P1. Accordingly, this state is identical with the one shown in FIG. 15, and the speed of the suction nozzle 78a relative to the printed board B is substantially zero.

The controller 69 executes shift control for the control valve 274 at a proper point of time immediately before the suction nozzle 78a reaches the mounting position P2. Thus, the control valve 274 is shifted from the suction position to the blow position. When the nozzle 78a reaches the mounting position P2, therefore, it releases its hold of the work W, and at the same time, securely mounts the work W in the mounting position P2 on the printed board B, with the aid of the blow pressure supplied from the pneumatic pressure source 258.

While the work W is mounted in this manner, the selector valve 274 is shifted to the low-pressure position by means of the controller 69, so that a low blow pressure is utilized for the work mounting.

Before the work W is mounted, the printed board B on the XY-table 8 is shifted in the X-direction and/or Y-direction in FIG. 2, and the mounting position P2 is previously set as the position for the work W on the board B.

If the posture of the work W is uncorrectable, the mounting operation for the work W is suspended. Thus, the suction nozzle 78a passes over the printed board B with the work W held thereon. Immediately before the nozzle 78a reaches the position over the opening 294 of the recovery container, thereafter, the controller 69 executes shift control for the control valve 254 and the selector valve 274. More specifically, at this point of time, the control valve 254 is shifted from the suction position to the blow position, while the selector valve 274 is shifted from the low-pressure position to the high-pressure position. Thus, the work W on the suction nozzle 78a is blown away toward the recovery container by means of a high blow pressure.

Thereafter, the work head 70 is changed to the posture shown in FIG. 16, and moved toward the target work feeder 6. Immediately before reaching this work feeder 6, the head 70 is restored to the posture shown in FIG. 14, and repeats the aforesaid operation.

When the controller 69 is supplied with a command for the change of the suction nozzle 78, it drives the second control motor 228. The driving force of the motor 228 is transmitted to the work head 70 through the toothed belt 224, input pulley 220, second sleeve shaft 156, output pulley 170, toothed belt 172, head driving pulley 106, and second spindle 100, and the head 70 is caused to rotate on its own axis to the rotational angle position where the selected suction nozzle faces downward. In this case, therefore, the selected nozzle, like the aforesaid suction nozzle 78a, is connected to the control valve 254 by means of the arcuate groove 138 and the control hole 142 of the control disk 132.

According to the chip mounter described above, the works can be continuously mounted on the printed board B by means of the suction nozzles 78 of each work head 70, without stopping the rotation of the lower drum 28.

Since the suction nozzles 78 of each work head 70 can receive the works on the work feeders 6 on any positions on the workbench 2, and mount the works on any positions on the printed board B, the mounting efficiency of the works can be greatly improved.

It is to be understood that the present invention is not limited to the embodiment described above, and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention.

Referring to FIG. 19, for example, there is shown a modification of the head unit. The head unit of this modification comprises input and output gears, used in place of the aforementioned input and output pulleys, and intermediate gears which replace the toothed belts. Since these input and output gears and intermediate gears have the same functions as their corresponding input and output pulleys and toothed belts, a description of those gears is omitted. In FIG. 19, the input and output gears and intermediate gears are designated by reference numerals obtained by affixing a subscript a to the numerals which are used to designate their corresponding input and output pulleys and toothed belts.

In connection with the foregoing embodiment, the first to third control motors 200, 228 and 230, control valve 254, and selector valve 274 on the side of the lower drum 28 have been described as being connected only electrically to the controller 69 in the upper drum 26. According to this modification, however, a connector unit shown in FIGS. 20 and 21 is used for the connection between these elements.

The connector unit comprises mating connectors 302 and 308, which have the same configuration. The one connector 302 is connected to the controller 69 by means of a cable 300. A cable 306, which extends from the other connector 308, is connected to the first to third control motors 200, 228 and 230, control valve 254, and selector valve 274 through a driver 304. The moment the mating connectors 302 and 308 are connected to each other, therefore, the electrical connection between the upper and lower drums 26 and 28 is established. Each of the connectors 302 and 308 has a stepped configuration, including a smaller end portion on its cable side.

The connector unit further comprises a holder plate 310 for the connectors 302 and 308. The plate 310 is horizontally fixed to the lower drum 28 (not shown in detail). A holder hole 312 is formed in the holder plate 310. The hole 312 is situated near an outer side edge of the plate 310, and has a size great enough to receive the smaller end portion of the connector 308. A notch 314 continuous with the holder hole 312 is formed in the aforesaid outer side edge of the holder plate 310.

According to the connector unit described above, the connectors 302 and 308 can be easily attached to the holder hole 312 of the holder plate 310 even though they are connected to each other. In attaching these connectors, the cable 306 of the connector 308 is first guided through the notch 314 into the holder hole 312, and the smaller end portion of the connector 308 is then inserted into the hole 312 from above. Thereupon, attaching the connectors 302 and 308 to the holder plate 310 is completed.

As described above, the connectors 302 and 308 can be securely held in position by only being inserted into the holder hole 312. During the operation of the chip mounter, the holder plate 310 is rotated together with the lower drum 28 at constant speed, so that the connectors 302 and 308 are pressed against the edge of the holder hole 312 by centrifugal force. Thus, no play can be caused between the connectors and the holder plate 310.

Meanwhile, the connectors 302 and 308 can be easily removed from the holder plate 310 by only being drawn out from the holder hole 310.

Further, the connectors 302 and 308 may be attached by using the brackets 236 (see FIG. 6) for the control motors in place of the holder plate 310. Preferably, however, the plate 310 should be located in a position near the outer peripheral portion of the lower drum 28 such that the connectors 302 and 308 are easily accessible from the outside.

Referring now to FIGS. 22 and 23, there is shown another chip mounter. This chip mounter comprises a plurality of carriers 400 in place of the lower drum 28. Each carrier 400 includes a carrier plate 401. One roller 402 is rotatably mounted on the central portion of the upper edge of the carrier plate 401, while a pair of spaced rollers 402 are rotatably mounted on the lower edge of the plate 401.

A pair of guide rails 404 are arranged above and below the carrier plate 401, individually, so that the carrier 400 can be run on the rails 404 by means of the rollers 402.

Chain conveyors 406 are connected to the carrier plate 401. The conveyors 406 and the guide rails 404 extend along a fixed transportation path, which may be an endless one or one having two opposite ends. Thus, when the chain conveyors 406 are run, the carrier 400 is transported together with the conveyors 406 along the guide rails 404 at constant speed.

The head unit 68 is supported on the carrier plate 401. More specifically, the first and second sleeve shafts 154 and 156 of the unit 68 extend through a bearing 408 and penetrate the plate 401.

In the case of this embodiment, the other end of the fixed shaft 152 is supported by the carrier 100, and the differential gear system 186 is provided on the first sleeve shaft 154. The system 186 includes an output pinion 410 in place of the output bevel gear 188. The pinion 410, which is mounted on the first sleeve shaft 154, is in mesh with a rack 412, which extends along the lower guide rail 404. The rack 412 is a member which corresponds to the ring gear 194.

Further, the output pinion 410 is attached to a ring gear 414 of the differential gear system 186. The gear 414 is in mesh with a plurality of planet gears 416, which are in mesh with a sun gear 418. The sun gear 418 is mounted on the first sleeve shaft 154. The input pulley 192 of the differential gear system 186 is mounted on a holder 420 for the planet gears 416.

A workbench (not shown) for work feeders is located under the head unit 68. The workbench extends along the guide rails 404, and the XY-table 8 is disposed in the middle of the workbench.

In the case of the chip mounter described above, the first sleeve shaft 154 rotates when the carrier 400 is moved along the guide rails 404, since the output pinion 410 of the differential gear system 186 is in mesh with the rack 412. Thus, as in the case of the foregoing embodiment, the work head 70 turns around the first sleeve shaft 154 without changing its posture, so that the downward suction nozzle 78 of the head 70 repeats cycloid motion along the guide rails 412. It is to be understood that the cycle of the cycloid motion can be varied by rotating the input pulley 192 of the differential gear system 186.

Also in the case of the chip mounter shown in FIGS. 22 and 23, therefore, the suction nozzle 78 of the work head 70 can attract a work to it from any desired work feeder on the workbench, and then mount the attracted work on a printed board on the XY-table.

Referring further to FIGS. 24 and 25, there is shown still another chip mounter. Although this chip mounter comprises a carrier which resembles that of the chip mounter shown in FIGS. 22 and 23, it is considerably different in the arrangement of the head unit 68.

The head unit 68 of this embodiment includes only one suction nozzle 78. The nozzle holder 76 of this nozzle 78 is supported on the carrier 400 by means of a four-joint link mechanism 500.

More specifically, the four-joint link mechanism 500 includes upper and lower rotating shafts 502 and 504 which penetrate the upper and lower portions, respectively, of the carrier plate 401. The lower rotating shaft 504 is a member which corresponds to the first sleeve shaft 154. The differential gear system 186 is mounted on the shaft 504.

One end of a first link 506 is mounted on one end of the upper rotating shaft 502, one end of a second link 508 on one end of the lower rotating shaft 504. The ratio between the respective lengths of the first and second links 506 and 508 is set at 1:1. The other end of each of the rotating shafts 502 and 504 is rotatably supported on a bearing member 510 which extends from the carrier 400.

Further, a pair of toothed pulleys 503 are mounted individually on the respective other end portions of the upper and lower rotating shafts 502 and 504, and a toothed belt 505 is passed around and between the pulleys 503. Thus, the rotating shafts 502 and 504 can rotate in the same direction at the same speed.

The other end of the first link 506 is rotatably mounted on one end of a third link 512 by means of a connecting shaft 514, and the other end of the third link 512 is rotatably mounted on the other end of the second link by means of a connecting pin 516.

The connecting shaft 514 projects from the third link 512, and a gear 522 is mounted on the projecting end of the shaft 514. A step motor 524 is mounted on the one end or upper end of the third link 512. The motor 524 is connected electrically to the controller 69. A gear 526 in mesh with the gear 522 is mounted on the output shaft of the step motor 524.

The proximal end of the nozzle holder 76 is mounted on the projecting end of the connecting shaft 514. The holder 76 extends downward through a guide 528, which protrudes from the third link 512. The suction nozzle 78 projects downward from the lower end of the holder 76. The guide 528 allows the nozzle holder 76 to rotate around the connecting shaft 514.

As mentioned before, the output pinion 410 of the differential gear system 186 is in mesh with the rack 412. When the carrier 400 is run along the guide rails 404, therefore, the lower rotating shaft 504 rotates, and at the same time, the upper rotating shaft 502 also rotates.

Since the rotation of the upper and lower rotating shafts 502 and 504 causes the third link 512 to turn through the medium of the first and second links 506 and 508, the nozzle holder 76 or the suction nozzle 78 turns without changing its downward posture. Also in the case of this embodiment, therefore, the suction nozzle 78 repeats cycloid motion as the carrier 400 travels. Also in this case, moreover, the cycle of the cycloid motion can be varied by rotating the input pulley 192 of the differential gear system 186 by means of the first control motor 200.

In this embodiment, the suction nozzle 78 is connected to the tube 146 through the connecting shaft 514, the first link 506, and a passage 520 formed in the upper rotating shaft 502. In FIG. 25, a blow pressure supply system for the suction nozzle 78 is omitted.

If the step motor 524 is driven, the nozzle holder 76 can be rotated for a predetermined angle by means of the connecting shaft 514. Thus, the region for the cycloid motion of the suction nozzle 78 can be raised with respect to the workbench. 

What is claimed is:
 1. A component mounting apparatus comprising:a component supply section disposed in a predetermined transportation path and having a plurality of supply positions arranged along the transportation path, the supply positions being successively supplied with components; a component mounting section disposed at a distance from the supply section, in the transportation path, and having a component mounting surface movable across the transportation path; a carrier repeatedly movable along the transportation path between the mounting section and the supply section; a component head provided on the carrier, the component head having a turning axis extending across the transportation path and including a suction nozzle with a distal end projecting from the component head toward the transportation path; turning means for turning the component head around the turning axis while keeping the component head in a fixed posture with respect to the transportation path, during the movement of the carrier, such that turning movement of said turning means during movement of the carrier causes cycloid motion of the distal end of the suction nozzle such that said distal end travels in a first cycloidal path along the transportation path; supply means for supplying suction pressure to the suction nozzle; control means for controlling the cycle of the cycloid motion of the suction nozzle and the supply of the suction pressure to the suction nozzle, the control means causing a component to be attracted to the distal end of the suction nozzle in one target supply position, and then releasing the component from the hold by the suction nozzle at the mounting surface, so that the component is mounted in the mounting surface; and separating means for causing movement of said distal end of said suction nozzle such that said distal end deviates from said first cycloidal path when the suction nozzle performs neither a component attracting operation nor a component mounting operation.
 2. A component mounting apparatus according to claim 1, wherein said work head has a rotation axis parallel to the turning axis, and said separating means includes changing means for rotating the component head for a predetermined rotational angle around the rotation axis thereof, thereby changing the posture of the suction nozzle with respect to the transportation path.
 3. A component mounting apparatus according to claim 2, wherein said supply means includes a suction passage in the component head, the suction passage having one end connected to the suction nozzle and the other end opening in the outer end face of the component head; a control disk in sliding contact with the outer end face of the component head, the control disk airtightly closing the other end opening of the suction passage and being prevented from rotating around the rotation axis of the work head; a control passage in the control disk, the control passage having one end opening in that surface of the control disk which is in sliding contact with the component head and the other end opening in the outer surface of the control disk, the other end opening being connected to a suction source by means of a suction line; and an arcuate groove formed in one of the respective sliding-contact surfaces of the component head and the control disk, the arcuate groove maintaining the connection between the other end opening of the suction passage and the one end opening of the control passage when the component head is caused to rotate for said predetermined rotational angle around the rotation axis.
 4. A component mounting apparatus according to claim 3, wherein said supply means further includes a blow line diverging from the middle of the suction line, a compressed air source connected to the blow line, and a control valve disposed at a diverging point between the blow line and the suction line, the control valve having two shift positions, including a suction position, in which the control passage of the control disk is connected to the suction source, and a blow position, in which the control passage is connected to the compressed air source, so that the control valve is shifted from the suction position to the blow position immediately before the suction nozzle mounts the work on the mounting surface.
 5. A component mounting apparatus according to claim 4, wherein said supply means further includes varying means for varying the blow pressure of compressed air supplied to the control passage through the control valve.
 6. A component apparatus according to claim 5, wherein said varying means includes a sub-line diverging from the middle of the blow line, a pressure reducing valve in the middle of the sub-line, and a selector valve disposed at a lower-course diverging point between the sub-line and the blow line, the selector valve having two shift positions, including a high-pressure position, in which the control valve is connected directly to the compressed air source, and a low-pressure position, in which the control valve is connected to the compressed air source through the pressure reducing valve.
 7. A component mounting apparatus according to claim 6, wherein said drum has a vertically extending drum shaft, and said suction line and said blow line of said supply means partially extend into the drum shaft.
 8. A component mounting apparatus according to claim 3, wherein said transportation path is circular in shape within a horizontal plane, said carrier includes a drum of which the outer periphery rotates over and along the transportation path, and said component head is arranged on the outer periphery of the drum so that the turning axis and the axis of rotation of the component head extend in the radial direction of the drum.
 9. A component mounting apparatus according to claim 8, wherein said component head includes a plurality of suction nozzles projecting radially with respect to the rotation axis, one of the suction nozzles facing downward to be opposed to the transportation path, said supply means includes suction passages connected individually to the suction nozzles, the respective other end openings of the suction passages being arranged at regular intervals on a circumference of a circle of an outer end face of the component head, and said arcuate groove is formed on the sliding-contact surface of the control disk and extends along the circumference of said circle, and which further comprises nozzle selecting means for rotating the component head around the rotation axis to position any desired suction nozzle in a downward posture.
 10. A component mounting apparatus according to claim 9, wherein said suction nozzles have different nozzle diameters.
 11. A component mounting apparatus comprising:a component supply section disposed along a predetermined transportation path and having a plurality of supply positions; a component mounting section disposed at a distance from the supply section along the transportation path; a carrier movable along the transportation path; a component head mounted upon said carrier for movement therewith, said component head including a distal end which holds a component as said carrier moves said component head from the component supply section to the component mounting section, with said distal end releasing said component at a desired position at said mounting section; revolving means for causing said component head to revolve about an axis of revolution, while maintaining a predetermined angular position of said distal end with respect to the transportation path and said carrier such that said distal end moves in a cycloidal path; and means for offsetting the angular position of said distal end with respect to said transportation path and said carrier.
 12. The component mounting apparatus of claim 11, wherein in a first predetermined angular position of said distal end said distal end extends in a vertically downward direction from said component head, and wherein said means for offsetting rotates said component head with respect to said carrier such that said distal end does not extend vertically downward, and wherein said means for offsetting causes rotation only when said distal end is neither retrieving nor releasing a component. 